When Albert claims that Bernard does not know Charlie’s birthday, he is saying that he knows that the correct day occurs more than once in the list. In other words, he is saying that Charlie’s birthday is not Feb 19, 2000, and the only way he could know that is that he knows that the month is not February.

So by making this claim Albert has reduced the list for everyone to:

• Apr 14, 1999
• Mar 14, 2000
• Mar 15, 2000
• Apr 16, 2000
• Apr 15, 2000
• Mar 15, 2001
• Apr 14, 2001
• Apr 16, 2001
• May 14, 2001
• May 16, 2001
• May 17, 2001

When Bernard says that it is true that he does not know Charlie’s birthday, it tells everyone that even with the restricted list the correct day occurs more than once in the list. So everyone can thus eliminate May 17, 2001.

Furthermore, the claim that Cheryl also does not know Charlie’s birthday is a claim that Bernard knows that the year occurs more than once on the remaining list.

This rules out Apr 14, 1999, and since Bernard could only rule this out by knowing that the day was not 14, everyone can further reduce the list to:

• Mar 15, 2000
• Apr 16, 2000
• Apr 15, 2000
• Mar 15, 2001
• Apr 16, 2001
• May 16, 2001

When Cheryl says that Albert still has not figured out Charlie’s birthday, she is telling everyone that given the new list the month occurs more than once and thus rules out May 16, 2001. This tells everyone that Cheryl knows that the year is not 2001 and the list can be reduced to:

• Mar 15, 2000
• Apr 16, 2000
• Apr 15, 2000

When Bernard then claims to know the date he is saying that the day occurs only once among the 3 remaining choices, thus telling everyone that Charlie’s birthday is Apr 16, 2000.

This solution is by Li Zhou of Polk Community College in Winter Haven, Florida. Draw an arrow on each domino that’s covering a black square, starting on the black square and continuing through the white square. Now every black square on the board (except for the one that was exposed at the start) is covered by the tail of an arrow, and each arrow points toward a neighboring black square.

This provides an answer. For any black square that’s covered at the start, the arrows now indicate a route leading to the uncovered black square. Shifting the dominoes along this route will uncover the chosen black square.

Will every such route find its way to the uncovered square? Yes. The alternative would be some “loop” of arrows within the diagram. Any such loop would enclose an odd number of squares, and such an interior could not be tiled by dominoes. So we know it doesn’t exist.

From the 1997 Russian Olympiad for high school students, via American Mathematical Monthly, April 2004 (Problem 10960). A solution using a graph model appears in the 1999 pamphlet Mathematical Olympiads 1997-1998: Problems and Solutions From Around the World, by T. Andreescu and K. Kedlaya.

555870 + 5550 + 5580 = 567000

974 + 3861307674 + 767430974 = 38144 + 7674 + 386130 + 4628307674

250 × 250 + 286 × 9378 = 431 × 6368

Add 0 to the start of the list, and pad out each entry to 10 digits by prepending zeroes:

0000000000
0000000001
0000000002
0000000003
0000000004
...
0999999996
0999999997
0999999998
0999999999
1000000000

Omit the final entry for the moment and pair the smallest entry in the remaining list with the largest, the second smallest with the second largest, and so on:

0000000000 + 0999999999 = 999999999
0000000001 + 0999999998 = 999999999
0000000002 + 0999999997 = 999999999
0000000003 + 0999999996 = 999999999
...

Each of these pairs produces the same sum, 999999999, the total of whose digits is 9 × 9 = 81. There are 500 million such pairs, so the sum of all those digits is 500,000,000 × 81, plus 1 from the last entry, 1,000,000,000, which we’d omitted above, giving a final total of 40,500,000,001.

From Ross Honsberger’s More Mathematical Morsels, 1991. Allegedly the 10-year-old Carl Friedrich Gauss had used the same trick as a schoolboy.

The only way to partition the 18 shots into 3 equal sets of 6 is:

25, 20, 20, 3, 2, 1
25, 20, 10, 10, 5, 1
50, 10, 5, 3, 2, 1

The first row must be Andryusha’s, since it’s the only one that contains two numbers totaling 22.

The score 3 appears only in the first and third rows, so the third must be Volodya’s. Thus he hit the bullseye.

From Boris Kordemsky’s The Moscow Puzzles, 1956.

Consider three squares in arithmetic progression, , , and . Then , or (a₃ – a₂)(a₃ + a₂) = (a₂ – a₁)(a₂ + a₁). We know that (a₂ + a₁) < (a₃ + a₂), so (a₂ – a₁) must be greater than (a₃ – a₂).

Now suppose that is an infinite arithmetic progression. Then

(a₂ – a₁) > (a₃ – a₂) > (a₄ – a₃) > … .

That’s impossible, since there’s no infinite decreasing sequence of positive integers. So the answer is no.

From Arthur Engel’s excellent Problem-Solving Strategies, 2008.

(a) 1/3
(b) 1/3
(c) 2/3
(d) 1/2

01/14/2026 UPDATE: Reader Catalin Voinescu sent this illustration:

(Thanks, Catalin.)

1. Qa8!

If the knight on a7 moves, then 2. Nc2 is mate.

If Black’s rook takes the knight, then 2. Qh8 is mate.

If Black’s rook moves along the second rank, White can capture it, giving mate.

And if the knight on d2 moves, then White’s rook on h2 captures Black’s on a2, giving mate. (If the knight captures the b1 bishop, then Rxb1 is mate.)

From the Norwich Mercury Tournament, 1902.